Efficient pulse Doppler radar with no blind ranges, range ambiguities, blind speeds, or Doppler ambiguities

1. A method of determining range information for a target comprising: generating a pulse signal comprising a train of transmit pulses, the transmit pulses having a pulse width, pulse waveform, and pulse repetition interval (PRI), at least two of which are each different for at least two consecutive pulses within the train of transmit pulses for a given Coherent Processing Interval (CPI), with the CPI defined by a set of transmit pulses in the train having a deterministic phase relationship of a reference frequency used to generate consecutive pulses; transmitting the pulse signal; receiving a return signal reflected from the target in response to transmitting; range processing the return signal in a radar signal processor, to determine range information for the target; and wherein the CPI is further divided into transmit pulse periods and receive pulse periods, with the transmit and receive pulse periods of arbitrary length within a CPI, but also such that a total transmit duty cycle, D, is uniform from CPI to CPI.

2. The method of claim 1 wherein range processing further comprises: Doppler processing the return signal at two or more Doppler offsets.

3. The method of claim 1 wherein the pulse width, pulse waveform, and pulse repetition interval are selected to provide equal energy in the return signal for different target ranges.

4. The method of claim 3 wherein the CPI is divided into a plurality of time bins of a selected bin duration, and the transmit and receive pulse periods are integer multiples of the selected bin duration.

5. The method of claim 1 wherein the arbitrary length is deterministic.

6. The method of claim 1 wherein the arbitrary length is pseudorandom.

7. The method of claim 1 wherein the arbitrary length is determined by an arithmetic algorithm.

8. The method of claim 1 wherein the pulse width and PRI are of arbitrary length, but with a constant duty cycle D achieved over a substantial set of consecutive transmit pulses within a CPI.

9. The method of claim 1 further comprising: radio frequency modulating the pulse signal prior to transmitting such that at least two successive pulses within the pulse train have different modulation; and radio frequency demoduling the return signal prior to range processing.

10. The method of claim 1 wherein transmit pulse width, pulse waveform, and pulse repetition interval (PRI) are each different for at least two consecutive pulses within a given Coherent Processing Interval (CPI).

11. The method of claim 1 wherein the different waveform comprises a random waveform, different coding, or different modulation for the at least two consecutive pulses.

12. An apparatus comprising: a pulse train signal generator, for generating a pulse signal comprising a train of transmit pulses, the transmit pulses having at least two of a pulse width, pulse waveform, and pulse repetition interval (PRI) that are each different for at least two consecutive pulses within the train of transmit pulses for a given Coherent Processing Interval (CPI), with the CPI defined by a set of transmit pulses in the train having a deterministic phase relationship of a reference frequency used to generate consecutive pulses; a transmitter for transmitting the pulse signal; a receiver for receiving a return signal; a range processor, for processing the return signal to determine range information for the target; and wherein the CPI is divided into a plurality of time bins of a selected bin duration, and the transmit and receive pulse periods are integer multiples of the selected bin duration.

13. The apparatus of claim 12 wherein the range processor further comprises: a Doppler processor comprising two or more Doppler offset sections.

14. The apparatus of claim 12 wherein the pulse width, pulse waveform, and pulse repetition interval are selected provide equal energy in the return signal for different target ranges.

15. An apparatus comprising: a pulse train signal generator, for generating a pulse signal comprising a train of transmit pulses, the transmit pulses having at least two of a pulse width, pulse waveform, and pulse repetition interval (PRI) that are each different for at least two consecutive pulses within the train of transmit pulses for a given Coherent Processing Interval (CPI), with the CPI defined by a set of transmit pulses in the train having a deterministic phase relationship of a reference frequency used to generate consecutive pulses; a transmitter for transmitting the pulse signal; a receiver for receiving a return signal; a range processor, for processing the return signal to determine range information for the target; and wherein the CPI is further divided into transmit pulse periods and receive pulse periods, with the transmit and receive pulse periods of arbitrary length within a CPI, but also such that a total transmit duty cycle, D, is uniform from CPI to CPI.

16. The apparatus of claim 15 wherein the arbitrary length is deterministic.

17. The apparatus of claim 15 wherein the arbitrary length is pseudorandom.

18. The apparatus of claim 15 wherein the arbitrary length is determined by an arithmetic algorithm.

19. An apparatus comprising: a pulse train signal generator, for generating a pulse signal comprising a train of transmit pulses, the transmit pulses having at least two of a pulse width, pulse waveform, and pulse repetition interval (PRI) that are each different for at least two consecutive pulses within the train of transmit pulses for a given Coherent Processing Interval (CPI), with the CPI defined by a set of transmit pulses in the train having a deterministic phase relationship of a reference frequency used to generate consecutive pulses; a transmitter for transmitting the pulse signal; a receiver for receiving a return signal; a range processor, for processing the return signal to determine range information for the target; and wherein the pulse width and PRI are of arbitrary length, but with a constant duty cycle D achieved over a substantial set of consecutive transmit pulses within a CPI.

20. The apparatus of claim 14 further comprising: a radio frequency modulator, for modulating the pulse signal such that at least two successive pulses within the transmitted pulse train have different modulation; and a radio frequency demodulator, for demodulating the return signal.

21. An apparatus comprising: a pulse train signal generator, for generating a pulse signal comprising a train of transmit pulses, the transmit pulses having at least two of a pulse width, pulse waveform, and pulse repetition interval (PRI) that are each different for at least two consecutive pulses within the train of transmit pulses for a given Coherent Processing Interval (CPI), with the CPI defined by a set of transmit pulses in the train having a deterministic phase relationship of a reference frequency used to generate consecutive pulses; a transmitter for transmitting the pulse signal; a receiver for receiving a return signal; a range processor, for processing the return signal to determine range information for the target; and wherein transmit pulse width, pulse waveform, and PRI are each different for at least two consecutive pulses within a given CPI.

22. The apparatus of claim 21 wherein the different pulse waveform comprises a signal with random properties, different coding, and/or different modulation for the at least two consecutive pulses within a CPI.

23. The apparatus of claim 21 wherein the reference frequency used to generate a selected pulse in the pulse train is identical to a reference frequency used to generate a consecutive pulse.